DM_Mach`s_ether_QCD_Vacx
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Transcript DM_Mach`s_ether_QCD_Vacx
Dark matter, Mach’s ether,
and the QCD vacuum
ArXiv: 1507.00460v2
Gilles Cohen-Tannoudji (LARSIM CEA Saclay)
LISHEP 2015 04/07/2015
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Outline
• Einstein’s address at the Leiden university, may 1920: search for a
Mach’s ether for general relativity
• LCDM and the dark matter issue
• The QCD vacuum in a cosmological context
• The hypothesis I submit to debate:
Dark energy + Dark matter = Mach’s ether
Dark matter = QCD vacuum
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The Mach’s ether of general relativity
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Albert Einstein
An address delivered in 1920, at the University
of Leiden
It is true that Mach tried to avoid having to accept as real something which is not observable by
endeavoring to substitute in mechanics a mean acceleration with reference to the totality of the
masses in the universe in place of an acceleration with reference to absolute space. But inertial
resistance opposed to relative acceleration of distant masses presupposes action at a distance; and
as the modern physicist does not believe that he may accept this action at a distance, he comes
back once more, if he follows Mach, to the ether, which has to serve as medium for the effects of
inertia. But this conception of the ether to which we are led by Mach's way of thinking differs
essentially from the ether as conceived by Newton, by Fresnel, and by Lorentz. Mach's ether not
only conditions the behavior of inert masses, but is also conditioned in its state by them.
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If we consider the gravitational field and the electromagnetic field from the standpoint of the ether
hypothesis, we find a remarkable difference between the two. There can be no space nor any part of
space without gravitational potentials; for these confer upon space its metrical qualities, without
which it cannot be imagined at all. The existence of the gravitational field is inseparably bound up
with the existence of space. (…) From the present state of theory it looks as if the electromagnetic
field, as opposed to the gravitational field, rests upon an entirely new formal motif, as though nature
might just as well have endowed the gravitational ether with fields of quite another type, for
example, with fields of a scalar potential, instead of fields of the electromagnetic type.
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Recapitulating, we may say that according to the general theory of relativity space is endowed with
physical qualities; in this sense, therefore, there exists an ether. According to the general theory of
relativity space without ether is unthinkable; for in such space there not only would be no
propagation of light, but also no possibility of existence for standards of space and time (measuringrods and clocks), nor therefore any space-time intervals in the physical sense. But this ether may not
be thought of as endowed with the quality characteristic of ponderable media, as consisting of parts
which may be tracked through time. The idea of motion may not be applied to it.
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An observational evidence for the Mach’s ether:
dark matter in astrophysics and cosmology
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Dark matter in astrophysics
Rotation curves of stars in galaxies and galaxies in clusters of galaxies
Rotation velocities do not decrease with distance at large distance
Dark matter invented to address this issue: a medium that exerts a gravitational
force that compensate the centrifugal force and prevent the rotating object to
escape from the system in which it rotates
Centrifugal force Fc=mv2/r , compensated by gravitational force M(r)m/r2 if
M(r)=lr i.e. the force exerted by a string with constant (independent of m and
of r) string tension
Dark matter acts as an ether exerting a gravitational force which derives from a
scalar potential
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Dark matter in cosmology: Review of the LCDM standard
model (WMAP confirmed by Planck 2015)
• Planck 2015 results:
The Planck TT, TE, and EE spectra are accurately described with a purely
adiabatic spectrum of fluctuations with a spectral tilt ns = 0.968 ± 0.006,
consistent with the predictions of single-field inflationary models.
Combining Planck data with BAO, we find tight limits on the spatial
curvature of the Universe, Wk<0.OO5, again consistent with the inflationary
prediction of a spatially-flat Universe.
By combining the Planck TT+lowP+lensing data with other astrophysical
data, including the JLA supernovae, the equation of state for dark energy is
constrained to w = -1.006 ± 0.045 and is therefore compatible with a
cosmological constant, as assumed in the base LCDM cosmology.
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L a2
Radiation dominance era
L a1.5
Matter dominance era
H L 1 1060 LP
Late inflation, CC dominance
era
H inf 1 103 LP
Primordial inflation
Today, a = 1
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The three stages of the LCDM model Hubble
radius L vs scale parameter a (set at 1 today) in log
scale
• Primordial inflation from a = 0 to point X. Between point P and point X
about 30 orders of magnitudes: at point X space is already flat.
• Hubble expansion between point X and point Y: era with L as a2
(radiation dominance) followed by era with L as a1.5 (matter
dominance)
• Late inflation, CC dominated between point Y and point Q
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A theoretical hint about the Mach’s ether:
the quantum vacuum
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The Friedman-Lemaître equations of motion
The Einstein equation
1
g 8 GN T Lg
2
Lg interpreted as the energy momentum tensor of the "vacuum"
Matter content of the universe, perfect fluid
T pg p u u
Friedman-Lemaître equations
2
R 8 GN k L
H
2
(1)
3
R
3
R
R L 4 G
3 p
R 3
3
2
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The quantum vacuum is not the nothingness
« D'où l'on peut voir qu'il y autant de différence
entre le néant et l'espace vide, que de l'espace
vide au corps matériel ; et qu'ainsi l'espace vide
tient le milieu entre le matière et le néant.» Réponse
de Blaise Pascal au très révérend père Noël, recteur de la Société de
Jésus, à Paris, 29 octobre 1647 Pascal, Oeuvres complètes, La Pléiade,
p 384, ed. 1998
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Consequences of the Heisenberg inequalities
• When the number of particles is well determined (for instance in the quantum
vacuum where this number is zero) the space-time state of the fields is not
determined: they fluctuate
• In space-time, the quantum vacuum can be assimilated to a complex medium,
seat of non scale invariant quantum fluctuations of the fields
• The properties of the quantum vacuum depend on the scale at which it is
probed. In cosmology, this scale is provided by the horizon radius which depends
on the cosmic time.
• If Mach’s ether is to be assimilated to the quantum vacuum, it has to depend on
the cosmic time
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Primordial inflation and the Brout Englert Gunzig mechanism
In the model proposed by Brout, Englert and Gunzig which could be compatible with the
primordial inflation phase of LCDM “quantum creation of massy particles can occur in the
cosmological context without cost of energy” R. Brout, F. Englert and E. Gunzig, The Creation of
the Universe as a Quantum Phenomenon, Annals of Physics 115, 78-106 (1978) (The BEG
mechanism ! )
The main point of their argument is that in homogeneous and isotropic cosmologies that obey
the cosmological principle, the metric is conformally flat, i.e. such that it is Minkowskian up to a
multiplicative factor related to its determinant which can be treated as a scalar field f in
Minkowski (flat) space-time.
This field gives rise to a negative energy density such that matter carrying positive energy can be
created and yet the total energy can be kept fixed and equal to the vacuum energy. This
apparent paradox is solved exactly in the same away as in the Brout Englert Higgs mechanism
electroweak symmetry breaking, the ghost that appears in the Landau ‘tHooft gauge is canceled
by the Nambu Goldstone boson in the unitary gauge.
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The QCD vacuum as an ether
The QCD Lagrangian, without quarks or with massless quarks (in the so-called chiral limit), is scale
invariant since the coupling constant is dimensionless. But through quantization, this symmetry is
broken, one says that it is dynamically broken: this phenomenon is called conformal anomaly.
The dynamical breaking of scale invariance is apparent in the fact that “the renormalization has
replaced a one-parameter family of unrenormalized theories, characterized by their values of the
dimensionless unrenormalized gauge coupling, g0 , by a one-parameter family of renormalized
theories, characterized by their value of the dimension-one [renormalization group invariant]
scale mass M(g,” (Stephen L. Adler, Einstein gravity as a symmetry breaking effect in quantum field
theory Review of Modern Physics, Vol 54, No 3, 729, 1982).This feature is also known as dimensional
transmutation
This scale mass, independent of the energy at which renormalization is performed, appears
as a non-vanishing trace of the renormalized energy-momentum tensor; it is completely
physical; it is related to the hadron masses; but, and this is the main point of our proposal, it
does have cosmological implications. Since the variation of the action with respect to the
metric, is proportional to the energy-momentum tensor, the scale factor of the metric,
represented by a scalar field f, is proportional to the trace of the energy-momentum tensor,
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Color confinement in QCD
Confinement superconductivity analogy
QCD vacuum = perfect color
diaelectric
e1
Superconductor =
perfect diamagnetic
1
e0
0
V (r ) l r
1
r2
l string tension
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The only way for such vacuum energy densities to contribute to the dark matter density is to be non relativistic
(namely cold), stable, and with only very weak non-gravitational interactions. It seems possible to satisfy all these
conditions with Bose Einstein Condensates (BEC): very low temperature at the Hubble horizon, superfluidity, a
characteristic of BEC.
It turns out that DM models involving such BECs have been successfully tried in the literature (Cosmic Structure as
the Quantum Interference of a Coherent Dark Wave by Hsi-Yu Schive, Tzihong Chiueh∗ & Tom Broadhurst
arXiv:1406.6586). In this reference, the authors show, by means of high precision simulations, that their Axion-like
model agrees with the conventional cold dark matter model in the description of large scale structures in the
distribution of galaxies and works much better than the conventional one in the description of small scale structure
thanks to interferences between the “dark quantum waves” and some waves arising in hydro-dynamical models
(Jeans effect).
Apart from ultralight bosons like the hypothetical Axion or scalar bosons, relics of the GUT symmetry breaking or of
some superstring dynamics, the only bosons susceptible to condense and to lead to observable cosmological effects
are the photon and the gluon. In fact weak intermediate and Higgs bosons are unstable and decay into light particles
in such a way that they contribute only to the radiation (or relativistic) component in the density budget of present
time and are thus negligible. The photon can condense (see the Casimir effect), but again it contributes only to the
radiation component and is negligible. There only remains the gluon
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Hubble radius L=H-1
Future event horizon
Today
E
F
LL
From radiation to matter dominance
D
LCDM cosmological SM
Color confinement
C
Past event horizon
HEP standard model
a
Linf
LP
w
B
A
10-60 Primeval inflation
Big-Bang ignition
Expansion
1
Late inflation
Scale factor
BSM physics
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Baryonic to dark matter energy density ratio and
the quark-gluon parton model
Scaling observed in deep inelastic lepton-nucleon scattering at the confinement scale (about 1.5
GeV2 ) leads to the parton distribution functions used as input in the standard model:
• Three valence “constituent quarks” (with a mass about 1/3 of the nucleon mass) carrying about
15% of the momentum of the nucleon
• “Sea” quark anti-quark pairs and gluons ( that is the QCD vacuum) carrying the remaining 85%
of the momentum of the nucleon
Once confined, the valence quarks give rise of the baryonic matter and the QCD vacuum gives rise
to the dark matter, with the good ration of energy densities
Quod erat demonstrandum!
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